1 | \section{Monte Carlo \label{sec:mc}}
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2 |
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3 | \subsection{Introduction \label{sec:mc:intro}}
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4 |
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5 | Many charasteristics of the extractor can only be investigated with the use of Monte-Carlo simulations~\cite{MC-Camera}
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6 | of signal pulses and noise for the following reasons:
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7 |
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8 | \begin{itemize}
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9 | \item While in real conditions, the signal can only be obtained in a Poisson distribution, simulated pulses of a specific
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10 | number of photo-electrons can be generated.
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11 | \item The intrinsic arrival time spread can be chosen within the simulation.
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12 | \item The noise auto-correlation in the low-gain channel cannot be determined from data,
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13 | but instead has to be retrieved from Monte-Carlo studies.
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14 | \item The same pulse can be studied with and without added noise, where the noise level can be deliberately adjusted.
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15 | \item The photo-multiplier and optical link gain fluctuations can be tuned or switched off completely.
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16 | \end{itemize}
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17 |
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18 | Nevertheless, there are always systematic differences between the simulation and the real detector. In our case, especially the
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19 | following short-comings are of concern:
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20 |
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21 | \begin{itemize}
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22 | \item The low-gain pulse is not yet simulated with the correct pulse width, but instead the same pulse shape as the one of the
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23 | high-gain channel has been used.
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24 | \item The low-gain pulse starts to saturate at already about 200 photo-electrons while in reality,
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25 | this limit lies at more than 500 photo-electrons for an inner pixel. This is due to the wider low-gain pulse in real conditions.
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26 | \item The low-gain pulse is delayed by only 15 FADC slices in the Monte-Carlo simulations, while it arrives about 16.5 FADC slices
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27 | after the high-gain pulse in real conditions.
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28 | \item No switching noise due to the low-gain switch has been simulated.
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29 | \item The intrinsic transit time spread of the photo-multipliers has not been simulated.
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30 | \item The pulses have been simulated in steps of 0.2\,ns before digitization. There is thus an artificial numerial time resolution
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31 | limit of $0.2\,\mathrm{ns}/\sqrt{12} \approx 0.06\,\mathrm{ns}$.
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32 | \item The total dynamic range of the entire signal transmission chain was set to infinite, thus the detector has been simulated
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33 | to be completely linear.
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34 | \end{itemize}
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35 |
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36 | For the subsequent studies, the following settings have been used:
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37 |
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38 | \begin{itemize}
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39 | \item The gain fluctuations for signal pulses were switched off.
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40 | \item The gain fluctuations for the background noise of the light of night sky were instead fully simulated, i.e. very close to
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41 | real conditions.
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42 | \item The intrinsic arrival time spread of the photons was set to be 1\,ns, as expected for gamma showers.
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43 | \item The conversion of total integrated charge to photo-electrons was set to be 7.8~FADC~counts
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44 | per photo-electron, independent of the signal strength.
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45 | \item The trigger jitter was set to be uniformly distributed over 1~FADC slice only.
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46 | \item Only one inner pixel has been simulated.
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47 | \end{itemize}
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48 |
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49 | The last point had the consequence that the extractor {\textit {\bf MExtractFixedWindowPeakSearch}} could not be tested since
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50 | it was equivalent to the sliding window.
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51 | In the following, we used the Monte-Carlo to determine especially the following quantities for each of the tested extractors:
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52 |
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53 | \begin{itemize}
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54 | \item The charge resolution as a function of the input signal strength.
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55 | \item The charge extraction bias as a function of the input signal strength.
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56 | \item The time resolution as a function of the input signal strength.
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57 | \item The effect of adding or removing noise for the above quantities.
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58 | \end{itemize}
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59 |
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60 | \subsection{Conversion Factors \label{sec:mc:convfactors}}
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61 |
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62 | The following figures~\ref{fig:mc:ChargeDivNphe_FixW} through~\ref{fig:mc:ChargeDivNphe_DFSpline} show the conversion factors
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63 | between reconstructed charge and the number of input photo-electrons for each of the tested extractors, with and without added noise
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64 | and for the high-gain and low-gain channels, respectively. One can see that the conversion factors depend on the extraction window size and
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65 | that the addition of noise raises the conversion factors uniformly for all fixed window extractors in the high-gain channel,
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66 | while the sliding window extractors show a bias a low signal intensities.
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67 |
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68 | \begin{figure}[htp]%%[t!]
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69 | \centering
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70 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_FixW_NoNoise_HiGain.eps}
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71 | \vspace{\floatsep}
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72 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_FixW_WithNoise_HiGain.eps}
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73 | \vspace{\floatsep}
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74 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_FixW_NoNoise_LoGain.eps}
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75 | \vspace{\floatsep}
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76 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_FixW_WithNoise_LoGain.eps}
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77 | \caption[Charge per Number of photo-electrons Fixed Windows]{Extracted charge per photoelectron versus number of photoelectrons,
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78 | for fixed window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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79 | low-gain regions. Left: without noise, right: with simulated noise.}
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80 | \label{fig:mc:ChargeDivNphe_FixW}
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81 | \end{figure}
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82 |
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83 | \begin{figure}[htp]
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84 | \centering
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85 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_SlidW_NoNoise_HiGain.eps}
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86 | \vspace{\floatsep}
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87 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_SlidW_WithNoise_HiGain.eps}
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88 | \vspace{\floatsep}
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89 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_SlidW_NoNoise_LoGain.eps}
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90 | \vspace{\floatsep}
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91 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_SlidW_WithNoise_LoGain.eps}
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92 | \caption[Charge per Number of photo-electrons Sliding Windows]{Extracted charge per photoelectron versus number of photoelectrons,
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93 | for sliding window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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94 | low-gain regions. Left: without noise, right: with simulated noise.}
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95 | \label{fig:mc:ChargeDivNphe_SlidW}
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96 | \end{figure}
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97 |
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98 | \begin{figure}[htp]
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99 | \centering
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100 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_DFSpline_NoNoise_HiGain.eps}
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101 | \vspace{\floatsep}
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102 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_DFSpline_WithNoise_HiGain.eps}
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103 | \vspace{\floatsep}
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104 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_DFSpline_NoNoise_LoGain.eps}
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105 | \vspace{\floatsep}
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106 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeDivNphevsNphe_DFSpline_WithNoise_LoGain.eps}
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107 | \caption[Charge per Number of photo-electrons Spline and Digital Filter]{Extracted charge per photoelectron versus number of photoelectrons,
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108 | for spline and digital filter extractors in different window sizes. The top plots show the high-gain and the bottom ones
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109 | low-gain regions. Left: without noise, right: with simulated noise.}
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110 | \label{fig:mc:ChargeDivNphe_DFSpline}
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111 | \end{figure}
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112 |
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113 | \clearpage
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114 |
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115 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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116 |
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117 | \subsection{Measurement of the Biases \label{sec:mc:baises}}
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118 |
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119 | We fitted the conversion factors obtained from the previous section in the constant region (above 10\,phe) and used
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120 | them to convert the extracted charge back to equivalent photo-electrons. After subtracting the simulated number of photo-electrons,
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121 | the bias (in units of photo-electrons) is obtained.
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122 | \par
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123 | Figure~\ref{fig:mc:ConversionvsNphe_FixW} through~\ref{fig:mc:ChargeRes_DFSpline} show the results for the tested extractors, with and
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124 | without added noise and for the high and low-gain regions separately.
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125 | \par
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126 | As expected, the fixed window extractor do not show any bias up to statistical precision. All sliding window extractor, however, do show
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127 | a bias. Usually, the bias vanishes for signals above 5--10~photo-electrons, except for the sliding windows with window sizes above
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128 | 8~FADC slices. There, the bias only vanishes for signals above 20~photo-electrons. The size of the bias as well as the minimum signal
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129 | strength above which the bias vanishes are clearly correlated with the extraction window size. Therefore, smaller window sizes yield
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130 | smaller biases and extend their linear range further downwards. The best extractors have a negligible bias above about 5 photo-electrons.
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131 | This corresponds to the results found in section~\ref{sec:pedestals} where the lowest image cleaning threshold for extra-galactic
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132 | noise levels yielded about 5 photo-electrons as well.
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133 | \par
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134 | All integrating spline extractors and all sliding window extractors with extraction windows above or equal 6 FADC slices
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135 | yield the comparably smallest biases. The rest results to be about a factor 1.5 higher. The spline and digital filter biases fall
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136 | down very steeply.
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137 |
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138 |
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139 | \begin{figure}[htp]%%[t!]
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140 | \centering
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141 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_FixW_NoNoise_HiGain.eps}
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142 | \vspace{\floatsep}
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143 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_FixW_WithNoise_HiGain.eps}
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144 | \vspace{\floatsep}
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145 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_FixW_NoNoise_LoGain.eps}
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146 | \vspace{\floatsep}
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147 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_FixW_WithNoise_LoGain.eps}
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148 | \caption[Bias Fixed Windows]{The measured bias (extracted charge divided by the conversion factor minus the number of photoelectrons)
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149 | versus number of photoelectrons,
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150 | for fixed window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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151 | low-gain regions. Left: without noise, right: with simulated noise.}
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152 | \label{fig:mc:ConversionvsNphe_FixW}
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153 | \end{figure}
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154 |
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155 | \begin{figure}[htp]
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156 | \centering
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157 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_SlidW_NoNoise_HiGain.eps}
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158 | \vspace{\floatsep}
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159 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_SlidW_WithNoise_HiGain.eps}
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160 | \vspace{\floatsep}
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161 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_SlidW_NoNoise_LoGain.eps}
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162 | \vspace{\floatsep}
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163 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_SlidW_WithNoise_LoGain.eps}
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164 | \caption[Bias Sliding Windows]{The measured bias (extracted charge divided by the conversion factor minus the number of photoelectrons)
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165 | versus number of photoelectrons,
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166 | for sliding window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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167 | low-gain regions. Left: without noise, right: with simulated noise.}
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168 | \label{fig:mc:ConversionvsNphe_SlidW}
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169 | \end{figure}
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170 |
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171 | \begin{figure}[htp]
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172 | \centering
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173 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_DFSpline_NoNoise_HiGain.eps}
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174 | \vspace{\floatsep}
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175 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_DFSpline_WithNoise_HiGain.eps}
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176 | \vspace{\floatsep}
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177 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_DFSpline_NoNoise_LoGain.eps}
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178 | \vspace{\floatsep}
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179 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ConversionvsNphe_DFSpline_WithNoise_LoGain.eps}
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180 | \caption[Bias Spline and Digital Filter]{The measured bias (extracted charge divided by the conversion factor minus the number of photoelectrons)
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181 | versus number of photoelectrons,
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182 | for spline and digital filter extractors in different window sizes. The top plots show the high-gain and the bottom ones
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183 | low-gain regions. Left: without noise, right: with simulated noise.}
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184 | \label{fig:mc:ConversionvsNphe_DFSpline}
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185 | \end{figure}
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186 |
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187 | \clearpage
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188 |
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189 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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190 |
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191 | \subsection{Measurement of the Resolutions \label{sec:mc:resolutions}}
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192 |
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193 | In order to obtain the resolution of a given extractor, we calculated the RMS of the distribution:
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194 |
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195 | \begin{equation}
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196 | R_{\mathrm{MC}} \approx RMS(\widehat{Q}_{rec} - Q_{sim})
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197 | \end{equation}
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198 |
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199 | where $\widehat{Q}_{rec}$ is the reconstructed charge, calibrated to photo-electrons with the conversion factors obtained in
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200 | section~\ref{sec:mc:convfactors}.
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201 | \par
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202 | One can see that for small signals, small extracion windows yield better resolutions, but extractors which do not
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203 | entirely cover the whole pulse, show a clear dependency of the resolution with the signal strength. In the high-gain region,
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204 | this is valid for all fixed window extractors up to 6~FADC slices integraion region, all sliding window extractors up to 4~FADC
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205 | slices and for all spline extractors and the digital filter. Among those extractors with a signal dependent resolution, the
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206 | digital filter with 6~FADC slices extraction window shows the smallest dependency, namely 80\% per 50 photo-electrons. This
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207 | finding is at first sight in contradiction with eq.~\ref{eq:of_noise} where the (theoretical) resolution depends only on the
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208 | noise intensity, but not on the signal strength. Here, the input light distribution of the simulated light pulse introduces the
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209 | amplitude dependency (the constancy is recovered for photon signals with no intrinsic input time spread). Here, the main
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210 | difference between the spline and digital filter extractors is found: At all intensities, but especially very low intensities, the
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211 | resolution of the digital filter is much better than the one for the spline.
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212 |
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213 | \begin{figure}[htp]
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214 | \centering
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215 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_FixW_NoNoise_HiGain.eps}
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216 | \vspace{\floatsep}
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217 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_FixW_WithNoise_HiGain.eps}
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218 | \vspace{\floatsep}
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219 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_FixW_NoNoise_LoGain.eps}
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220 | \vspace{\floatsep}
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221 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_FixW_WithNoise_LoGain.eps}
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222 | \caption[Charge Resolution Fixed Windows]{The measured resolution (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons,
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223 | for fixed window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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224 | low-gain regions. Left: without noise, right: with simulated noise.}
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225 | \label{fig:mc:ChargeRes_FixW}
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226 | \end{figure}
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227 |
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228 | \begin{figure}[htp]
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229 | \centering
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230 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_SlidW_NoNoise_HiGain.eps}
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231 | \vspace{\floatsep}
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232 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_SlidW_WithNoise_HiGain.eps}
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233 | \vspace{\floatsep}
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234 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_SlidW_NoNoise_LoGain.eps}
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235 | \vspace{\floatsep}
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236 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_SlidW_WithNoise_LoGain.eps}
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237 | \caption[Charge Resolution Sliding Windows]{The measured resolution (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons,
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238 | for sliding window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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239 | low-gain regions. Left: without noise, right: with simulated noise.}
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240 | \label{fig:mc:ChargeRes_SlidW}
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241 | \end{figure}
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242 |
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243 | \begin{figure}[htp]
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244 | \centering
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245 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_DFSpline_NoNoise_HiGain.eps}
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246 | \vspace{\floatsep}
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247 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_DFSpline_WithNoise_HiGain.eps}
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248 | \vspace{\floatsep}
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249 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_DFSpline_NoNoise_LoGain.eps}
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250 | \vspace{\floatsep}
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251 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_ChargeRes_DFSpline_WithNoise_LoGain.eps}
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252 | \caption[Charge Resolution Spline and Digital Filter]{The measured resolution
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253 | (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons,
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254 | for spline and digital filter extractors in different window sizes. The top plots show the high-gain and the bottom ones
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255 | low-gain regions. Left: without noise, right: with simulated noise.}
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256 | \label{fig:mc:ChargeRes_DFSpline}
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257 | \end{figure}
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258 |
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259 | \clearpage
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260 |
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261 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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262 |
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263 | \subsection{Arrival Times \label{sec:mc:times}}
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264 |
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265 | Like in the case of the charge resolution, we calculated the RMS of the distribution of the deviation of the
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266 | reconstructed arrival time with respect to the simulated time:
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267 |
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268 | \begin{equation}
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269 | \Delta T_{\mathrm{MC}} \approx RMS(\widehat{T}_{rec} - T_{sim})
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270 | \end{equation}
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271 |
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272 | where $\widehat{T}_{rec}$ is the reconstructed arrival time and $T_{sim}$ the simulated one.
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273 | \par
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274 | Generally, the time resolutions $\Delta T_{\mathrm{MC}}$ are about a factor 1.5 better than those obtained
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275 | from the calibration (section~\ref{sec:cal:timeres}, figure~\ref{fig:time:dep}). This
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276 | is understandable since the Monte-Carlo pulses are smaller and
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277 | further the intrinsic time spread of the photo-multiplier has not been simulated. Moreover, no time resolution offset was
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278 | simulated, thus the reconstructed time resolutions follow about a $1/\sqrt{N_{\mathrm{phe}}}$\,--\,behaviour over the whole low-gain range.
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279 | The spline extractors level off in contradiction to what has been found with the calibration pulses.
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280 | \par
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281 | In figure~\ref{fig:mc:TimeRes_SlidW}, one can see nicely the effect of the addition of noise to the reconstructed time
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282 | resolution: While without noise all sliding window extractors with a window size of at least 4~FADC slices show the same time
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283 | resolution, with added noise, the resolution degrades with larger extraction window sizes. This can be understood by the fact that
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284 | an extractor covers the whole pulse if integrating at least 4~FADC slices and each additional slice can only be affected by the noise.
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285 |
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286 | \begin{figure}[htp]
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287 | \centering
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288 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_SlidW_NoNoise_HiGain.eps}
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289 | \vspace{\floatsep}
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290 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_SlidW_WithNoise_HiGain.eps}
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291 | \vspace{\floatsep}
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292 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_SlidW_NoNoise_LoGain.eps}
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293 | \vspace{\floatsep}
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294 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_SlidW_WithNoise_LoGain.eps}
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295 | \caption[Time Resolution Sliding Windows]{The measured time resolution (RMS of extracted time minus simulated time)
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296 | versus number of photoelectrons,
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297 | for sliding window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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298 | low-gain regions. Left: without noise, right: with simulated noise.}
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299 | \label{fig:mc:TimeRes_SlidW}
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300 | \end{figure}
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301 |
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302 | \begin{figure}[htp]
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303 | \centering
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304 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_DFSpline_NoNoise_HiGain.eps}
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305 | \vspace{\floatsep}
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306 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_DFSpline_WithNoise_HiGain.eps}
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307 | \vspace{\floatsep}
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308 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_DFSpline_NoNoise_LoGain.eps}
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309 | \vspace{\floatsep}
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310 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_TimeRes_DFSpline_WithNoise_LoGain.eps}
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311 | \caption[Time Resolution Spline and Digital Filter]{The measured time resolution (RMS of extracted time minus simulated time)
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312 | versus number of photoelectrons,
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313 | for spline and digital filter window extractors in different window sizes. The top plots show the high-gain and the bottom ones
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314 | low-gain regions. Left: without noise, right: with simulated noise.}
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315 | \label{fig:mc:TimeRes_DFSpline}
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316 | \end{figure}
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317 |
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318 |
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319 | %%% Local Variables:
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320 | %%% mode: latex
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321 | %%% TeX-master: "MAGIC_signal_reco"
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322 | %%% End:
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323 |
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324 |
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325 |
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326 |
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327 |
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328 |
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329 |
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330 |
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331 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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332 |
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333 | \clearpage
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334 |
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335 | \subsection{Charge Signals with and without Simulated Noise \label{fig:mc:sec:mc:chargenoise}}
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336 |
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337 |
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338 | \begin{figure}[htp]
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339 | \centering
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340 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_SlidW_HiGain.eps}
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341 | \vspace{\floatsep}
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342 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_FixW_HiGain.eps}
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343 | \vspace{\floatsep}
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344 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_DFSpline_HiGain.eps}
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345 | \caption[Bias due to noise high-gain]{Bias due to noise: Difference of extracted charge of same events, with and without simulated noise,
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346 | for different extractor methods in the high-gain region.}
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347 | \label{fig:mc:Bias_HiGain}
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348 | \end{figure}
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349 |
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350 | \begin{figure}[htp]
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351 | \centering
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352 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_SlidW_LoGain.eps}
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353 | \vspace{\floatsep}
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354 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_FixW_LoGain.eps}
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355 | \vspace{\floatsep}
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356 | \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_DFSpline_LoGain.eps}
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357 | \caption[Bias due to noise low-gain]{Bias due to noise: Difference of extracted charge of same events, with and without simulated noise,
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358 | for different extractor methods in the low-gain region.}
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359 | \label{fig:mc:Bias_LoGain}
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360 | \end{figure}
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